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Series 300 Valves
Edition 02/2018
4
General Information
• The capability to regulate near zero flow, as standard on all sizes, eleminates the need for a special low flow (throttling plug) or valve, while ensuring very low head loss in “fully open” position.
• The flange (face-to-face) dimensions suit ISO Standards.
• The valve has an internal floating shaft, allowing for frictionless operation. The unique design of the shaft provides for easy field maintenance.
• The valve has a resilient seal disc, guided by a frictionless centering device.
• The valve’s body is made of Ductile Iron, withstanding both high hydraulic and mechanical stresses.
• The standard single - chamber valve provides smooth operation in sensitive regulation
conditions. When required, conversion from a single to a double chambered valve is easily accomplished through the insertion of Dorot’s innovative separation disc, without the need to remove the valve from the pipeline during the conversion.
• The valve is supplied with a replaceable Stainless Steel seat, which maintains excellent durability against erosion and ensures a drip-tight seal.
• During valve closure the rate slows, preventing potential damage from water hammer or surges.
• The 300 Series includes an optional valve position indicator, attached by a floating connection (ball & socket), resulting in smooth movement, with no wear or tear on the indicator seal.
Features of the 300 Series
Position indicator (optional)
Spring
Stainless Steel inserts
Diaphragm discs
Fully guided stem
Seal discs
Seat
Centering guide
Air release nut
Suspension hook
Fully supported Diaphragm
Double Chamber disc (optional)
Rubber seal
Stainless Steel internal parts
Drainage bore (optional)
Overview DOROT’S 300 Series, state-of-the-art automatic control valves are designed to withstand the most demanding requirements of water system control. The experts at DOROT developed this technically-advanced valve with capabilities- far beyond any other on the market.This Engineering Data guide will asist the reader in the selection of the optimal DOROT Series 300 valve.
Features
Self Flushing filter
Series 300 Valves
Edition 02/2018
5
Engineering Data
Technical SpecificationsParameter Standard Optional
Connections • Flanged ISO 7005 or ANSI B16• Threaded BSP or NPT
• Flanged AS10, JIS B22, ABNT and others
Pressure range
• Model 30: 0.5 – 16 bar 7 – 250 psi
• Models 31, 32: 0.5 – 25 bar 7 – 360 psi
• 0 min. press. with N.O spring assisted opening.
• 0.2 bar / 3 psi min. pressure without a spring
Note: both options require usage of external higher closing pressure
Max. Water Temperature • 80ºC / 180ºF • 95ºC / 200ºF
MaterialsPart Standard Optional
Body & Cover Ductile Iron GGG50 (ASTM A-536)
Cast Steel A-216 WCBCast Bronze or Marine BronzeCast SST CF8M (316)Ni Aluminum BronzeOthers
Main Valve Internals SST, Bronze and Coated Steel SST 316, HASTELLOY, SMO, DUPLEX
Spring SST 302 SST 316, INCONNEL
Diaphragm Nylon fabric reinforced EPDM (WRAS and NSF approved) NBR, Viton
Seals EPDM NBR, Viton
Coating Polyester RAL 5010
FBE RAL 5010Polyester RAL3000 (fire red)UV protected FBE RAL3000Rilsan (Nylon)Halar
Control Trim: Fittings and control devices Brass SST 304SST 316, Duplex
Control Trim: Tubes Reinforced, heavy-duty Nylon, Polypropylene
CopperSST 316, Duplex
Note: The Dorot S-300 valves in all sizes, meet the USA amendment for reducing lead in drinking water marked as S.3874 dated 01.05.2010.
Series 300 Valves
Edition 02/2018
6
Engineering Data
Standard (Single Chamber) ValveClosed Mode: The control pressure (taken from the pipeline) is applied by the control device to the control chamber (top of the diaphragm). The pipeline pressure pushes the seal to open, and the control chamber pressure forces the diaphragm to close. Since the diaphragm area is larger than the seal area, it has greater hydraulic force so the valve remains in the closed position.
Open Mode: The control device relieves the pressure from the control chamber. The pipeline pressure forces the seal to the “open” position so that the fluid can pass through the valve. While the valve is open, outlet pressure is applied to the lower side of the diaphragm, assisting the opening.
Double Chamber Valve (Version D)The double chamber version is created by inserting a separation disc between the diaphragm and the seal. This assembly creates a second control chamber below the diaphragm, permitting for the activation of the valve in low-pressure systems and enabling the activation faster valve response. The response to varying conditions is quick, since closure downward movement is not resisted by pressure below the diaphragm.
Closed Mode: The control pressure (taken from the pipeline or from supplementary pressure source) is applied to the top of the external diaphragm. The bottom control chamber drains. The pipeline pressure pushes the seal to open, but since the diaphragm area is larger than the seal area it creates greater hydraulic force and which forces the valve to close thus the valve closes. At this stage, the bottom chamber should be drained.
Open Mode: The control device releases the pressure from the top control chamber.The seal assembly is forced to the “open” position by the pipeline pressure, allowing flow through the valve.
Closed Mode
Opened Mode
Closed Mode
Opened Mode
Basic Valve Operating Modes On-Off Mode
Closed Mode
Open Mode
Closed Mode
Open Mode
D chamber - Closed Mode
D chamber - Open Mode
ControlDevice
SeparationDisc
ControlDevice
D chamber - Closed Mode
D chamber - Open Mode
ControlDevice
SeparationDisc
ControlDevice
Series 300 Valves
Edition 02/2018
7
Engineering Data
Modulating ModeGeneralPositioning the seal a short distance (less than 1/4 of the seat diameter) from the seat, creates friction and turbulence, causing energy loss in the fluid passing through the valve. The results are: - Reduction of pressure and flow rate.- Increase of inlet pressure.The position of the seal assembly is dictated by the volume of control fluid in the top control chamber, which is determined by the control device. The control device is operated by hand (manual control), by electric current (solenoid valve), or by hydraulic pressure (pilot valves, hydraulic relays). All can be used in standard (single chamber) valves as well as in double chamber valves.
Modulating mode in standard (single chamber) valves
Regulation at high pressures differenceThe S-300 has exceptional resistance to damages, caused by cavitation conditions. This feature was certified by extensive tests, carried by an independent laboratories in US and Europe. The operation limits, as found in these tests, can be calculated for any specific location- using a simple computer program (supplied on request). For operation conditions that exceed the safe limit- a special Cavitation-Free valve can be supplied. This version, marked by the suffix “F” (example 30F-3 is a cavitation-free, 80mm / 3” valve), can operate at any pressure differential without being ruined by it. The internal structure includes a Stainless Steel, perforated cylinder, that is connected below the standard seal disc and moving freely inside the seat. The valve is assembled to generate “over the seat” flow, so the water stream enters the cylinder from its external side and emerges through the internal side. The energy is dissipated by the high-velocity, turbulent flow through the exposed holes above the seat (due to varying trim position). The pressure recovery, that is the cause of cavitation damage, happens now inside the cylinder and not adjacent to the body wall. As the SST material is highly- resistant to cavitation- it is not damaged.
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Fully Open
Power-Opening ModeDouble Chamber ValveThis operating mode is selected when the control pressureis taken from an external source ( a water system withhigher pressure, compressed air, etc...) rather than fromthe pipeline. This mode is usually selected when pipelinepressure is extremely low. The control system is able topressurize one chamber while simultaneously draining theother one.
Closed Mode: The control device applies pressure tothe top chamber while draining the bottom chamber. Thediaphragm is forced down, causing the seal to close thewater passage.
2002G3-b
Open Mode: The control device releases the pressurefrom the top control chamber and applies pressure to thebottom control chamber. The seal assembly is forced to the"open" position, allowing flow through the valve.
Closed Mode
SeparationDisc
Open Mode
ControlDevice
ControlDevice
Closed
Regulating
Modulating Mode
GeneralPositioning the seal a short distance (less than 1/4 of theseat diameter) from the seat, creates friction and turbulence,causing energy loss in the fluid passing through the valve.The results are:-Reduction of pressure and flow rate.-Increase of inlet pressure.The position of the seal assembly is dictated by the volumeof control fluid in the top control chamber which is determinedby the control device.The control device is operated by hand (manual control), byelectric current (solenoid valve), or by hydraulic pressure(pilot valves, hydraulic relays). All can be used in standard(single chamber) valves as well as in double chamber valves.
Modulating mode in standard (single chamber) valves.
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Fully Open
Power-Opening ModeDouble Chamber ValveThis operating mode is selected when the control pressureis taken from an external source ( a water system withhigher pressure, compressed air, etc...) rather than fromthe pipeline. This mode is usually selected when pipelinepressure is extremely low. The control system is able topressurize one chamber while simultaneously draining theother one.
Closed Mode: The control device applies pressure tothe top chamber while draining the bottom chamber. Thediaphragm is forced down, causing the seal to close thewater passage.
2002G3-b
Open Mode: The control device releases the pressurefrom the top control chamber and applies pressure to thebottom control chamber. The seal assembly is forced to the"open" position, allowing flow through the valve.
Closed Mode
SeparationDisc
Open Mode
ControlDevice
ControlDevice
Closed
Regulating
Modulating Mode
GeneralPositioning the seal a short distance (less than 1/4 of theseat diameter) from the seat, creates friction and turbulence,causing energy loss in the fluid passing through the valve.The results are:-Reduction of pressure and flow rate.-Increase of inlet pressure.The position of the seal assembly is dictated by the volumeof control fluid in the top control chamber which is determinedby the control device.The control device is operated by hand (manual control), byelectric current (solenoid valve), or by hydraulic pressure(pilot valves, hydraulic relays). All can be used in standard(single chamber) valves as well as in double chamber valves.
Modulating mode in standard (single chamber) valves.
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Fully Open
Power-Opening ModeDouble Chamber ValveThis operating mode is selected when the control pressureis taken from an external source ( a water system withhigher pressure, compressed air, etc...) rather than fromthe pipeline. This mode is usually selected when pipelinepressure is extremely low. The control system is able topressurize one chamber while simultaneously draining theother one.
Closed Mode: The control device applies pressure tothe top chamber while draining the bottom chamber. Thediaphragm is forced down, causing the seal to close thewater passage.
2002G3-b
Open Mode: The control device releases the pressurefrom the top control chamber and applies pressure to thebottom control chamber. The seal assembly is forced to the"open" position, allowing flow through the valve.
Closed Mode
SeparationDisc
Open Mode
ControlDevice
ControlDevice
Closed
Regulating
Modulating Mode
GeneralPositioning the seal a short distance (less than 1/4 of theseat diameter) from the seat, creates friction and turbulence,causing energy loss in the fluid passing through the valve.The results are:-Reduction of pressure and flow rate.-Increase of inlet pressure.The position of the seal assembly is dictated by the volumeof control fluid in the top control chamber which is determinedby the control device.The control device is operated by hand (manual control), byelectric current (solenoid valve), or by hydraulic pressure(pilot valves, hydraulic relays). All can be used in standard(single chamber) valves as well as in double chamber valves.
Modulating mode in standard (single chamber) valves.
Closed
Fully Open
Regulating
Closed Valve
Fully-opened Valve
Cavitation energy dissipation area
Series 300 Valves
Edition 02/2018
8
Engineering Data
2-Way Control DeviceThe 2-way control device is assembled on a control circuit, connecting upstream to downstream through the control chamber.There are two restrictors assembled in this circuit:(a) A nozzle or a needle valve, at a fixed opening.(b) A modulating device (pilot), whose passage may vary from complete closure (b=o) to a fully open size (when b>a).The volume of the control media in the chamber is determined by the relative passages (a) and (b), or, in fact, by the opening of (b), as (a) is fixed.
Closed Mode: Pilot (b) senses a downstream pressure higher than the set-point and closes passage (b). Through passage (a) the upstream water flows directly into the upper part of the control chamber, forcing the diaphragm to close the valve.
Open Mode: Pilot (b) senses a downstream pressure lower than the set-point, and fully opens passage (b), larger than (a). All the water from the upstream flows through (a) and (b), directly to the downstream, allowing water from the upper part of the control chamber to partially drain until the pressure in the chamber equals the downstream pressure.Pressure in the upper part of the control chamber is decreased and the upstream water pressure forces the seal disc to rise (opening the valve).
Regulating Mode: The pilot is set to the required downstream pressure. The pilot senses when the downstream pressure reaches the required value causing passage (b) to equal passage (a) b=a. Now, water that flows through the control loop passes from (a) through (b) and into the downstream. The control media in the upper part of the control chamber is now steady, keeping the diaphragm and seal in a fixed position. Any change in the downstream pressure will change the b=a balance. This change adds or drains water from the control chamber, thus opening or closing the main valve until it reaches the balanced regulating position b=a once again.
The 2-way control device provides sensitive, accurate, and constant modulating, control of the main valve. The main valve does not fully open, as the control device prevents total draining of the control chamber.The 2-way control device is standard in most pressureregulating valves.
Closed Valve
Opened Valve
Closed Valve
Regulating Valve
Regulating Valve
Closed Mode
Open Mode
Closed Mode
Open Mode
Series 300 Valves
Edition 02/2018
9
Engineering Data
3-Way Control DeviceThe 3-way control device is a small selector valve which:1. Permits passage of the control media into the
main valve control chamber (initiating the “closing” procedure), or
2. Permits drainage of the control media from the control chamber to the atmosphere (initiating the “opening” procedure).
Some of the 3-way control devices have a third mode as well, which prevents inflow or outflow from the control chamber, so that the main valve remains fixed when the device is in this mode.The 3-way mode is used in on-off valves or when the regulating valve is fully open, in order to obtain specific operating conditions. Once in position, there is no water flow through the control chamber.The 3-way control circuit may open the main valve entirely, creating minimum head loss.The 3-way control device must be used when external media (not pipeline water) is used to control the valve, or when the control media is dirty or abrasive.
Proportional Pressure ReducerThe proportional pressure reducer is a valve that has a control chamber permanently connected to the downstream.This valve must be a double chamber [D] type.The balance of hydraulic forces created between the high pressure on the small seal area, and the lower downstream pressure on the larger diaphragm area, causes a fixed ratio of inlet/outlet pressure of approximately 3:1.No other control device is needed.
Closed Valve
Opened Valve
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2002G3-d
Non-Return (Check Valve) ModeDouble Chamber ValveFlow in the normal direction forces the seal to the "open"position, allowing for free flow. When downstream pressureexceeds upstream pressure, return flow may occur, causingthe seal disc to instantly close as a result of both hydraulicforce and the spring's force.
Proportional Pressure ReducerThe proportional pressure reducer is a valve that has a controlchamber permanently connected to the downstream.This valve must be a double chamber [D] type.The balance of hydraulic forces created between the highpressure on the small seal area, and the lower downstreampressure on the larger diaphragm area, causes a fixed ratioof inlet/outlet pressure of approximately 3:1.
No other control device is needed.
Regular Flow
Return Flow
Closed Valve
Open Valve
3-Way Control DeviceThe 3-way control device is a small selector valve which:1.Permits passage of the control media into the main valvecontrol chamber (initiating the "closing" procedure),or2. Permits drainage of the control media from the controlchamber to the atmosphere (initiating the "opening" procedure).
Some of the 3-way control devices have a third mode aswell, which prevents inflow or outflow from the controlchamber, so that the main valve remains fixed when thedevice is in this mode.This mode is used in on-off valves or when the regulatingvalve is fully open, in order to obtain specific operatingconditions. Once in position, there is no water flow throughthe control chamber.The 3-way control device may open the main valve entirely,creating minimum head loss.The 3-way control device must be used when external media(not pipeline water) is used to control the valve, or whenthe control media is abrasive.
Separation Disc
Closed Mode
Open Mode
Closed Mode
Open Mode
Series 300 Valves
10
Edition 02/2018
0
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100
0 0.1 0.2 0.3 0.4 0.5 0.6 0.7KnKv
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9.2.2001 10.2.2001 11.2.2001 12.2.2001 13.2.2001 14.2.2001 15.2.2001 16.2.20010
1
2
3
4
5
6
7
8
9
0.8 0.9 1.0
Engineering Data
Typical Pressure Reducing Performance Chart
Comparison of different seal structures
100 mm / 4” Dorot 300 Series Pressure Reducing Valve
%
Unstable regulation zone
Pres
sure
Met
res
Outlet Pressure
* Independent laboratory report data source
Pressures logged at 1 Minute Intervals
Flow logged at 15 Minute intervals
Inlet Pressure
LTP Design (s-300 Valve)*
Saughton Hall under 100mm DOROT 300 Series CX Pilot Control
Flow Litre/sec
Flow
Valv
e op
enin
g
V-Plug U-Plug Flat-Disk plug
Series 300 Characteristic Curve Comparisonwithcompetitivedesigns
Series 300 Valves
Edition 02/2018
11
Engineering Data
Cavitation Data
10 20 30 40 50 60 70 80 mwc
Outlet pressure
10 30 50 60 70 90 100 110 psi 80 40 20
0
10
20
30
40
50
60
70
80
90
100
110
120
130
140
150
160
170
180
190
200
210
220
230
240
250
20
40
60
80
100
120
140
160
180
200
220
240
260
280
300
320
340
360 mwc psi
Inlet pressure
Case- III
Case- II
Case- I
Destructive Cavitation
Noisy Operating
Safe Operating conditions
Cavitation Chart Limits of operating conditionsThe chart above sets the safe limits for valves that are supposed to operate at a considerable pressure differential.Such conditions generate noise and possible cavitation damages to the valve body.How to use the chart:i. Determine the maximal dynamic pressure that may be applied in the inlet of the valve.ii. Draw an horizontal line from the pressure scale at the left side of the chartiii. Find the requested outlet pressure in the pressure scale at the bottom of the chart.iv. Draw an upward line at this point.v. The intersection of the two lines defines the cavitation characteristics of the valve operation.
- In the case that it falls in the RED zone (case I)- the valve may be damaged in a fairly short time.- In the case that it falls in the YELLOW zone (case II)- the valve may generate a noise that exceeds 80db.- In the case that the intersection is within the GREEN zone (case III)- the valve will perform safely and quietly
General remark: The cavitation and noise data are based on tests done by the Utah State University, US, and Delft Hydraulic Laboratories, Holland.
Inlet pressure
Outlet pressure
Destructive Cavitation
NoisyOperating
Case 1
Case 2
Case 3
Safe OperatingConditions
Series 300 Valves
Edition 02/2018
12
Engineering Data
Dimensions & WeightsModels 30 (16 bar rated valves) / 31 (25 bar rated valves)
H
L
W
AH
AR
AL
TH
TR
TL
R
TW
AB
h h
AW
H
L
W
AH
AR
AL
TH
TR
TL
R
TW
AB
h h
AW
Globe Flanged Type Valve Size 40 (11/2”) 50 ( 2”) 65 (21/2”) 80 (3”) 100 (4”) 150 (6”) 200 (8”) 250 (10”)
mm inch mm inch mm inch mm inch mm inch mm inch mm inch mm inchL
L (ANSI#300)H
h**WR
23023018514015382.5
91/16
91/16
75/16
51/2
631/4
23023518514017082.5
91/16
23/16
75/16
51/2
611/16
31/4
29029218514018592.5
113/8
121/2
75/16
51/2
73/16
35/8
310345230170200100
123/16
131/2
91/16
611/16
77/8
315/16
350400240180235110
133/4
1511/16
97/16
791/4
45/16
480525330230330
142.5
187/8
205/8
1391355/8
600605390300415
172.5
235/8
2313/16
153/8
1113/16
165/16
63/4
730790520390525205
283/4
311/8
201/2
151/4
2011/16
81/16
Weight Kg/Ibs* 12 / 26 12 / 26 13 / 29 22 / 49 37 / 82 80 / 176 157 / 346 245 / 540Vol.control
chamber lit/gal 0.1 / 0.02 0.1 / 0.02 0.1 / 0.02 0.3 / 0.08 0.7 / 0.2 1.5 / 0.4 4.3 / 1.1 9.7 / 2.6
Valve Size 300 (12”) 350 (14”) 400 (16”) 450 (18”) 500 (20”) 600 (24”) 700 (28”) 800 (32”)mm inch mm inch mm inch mm inch mm inch mm inch mm inch mm inch
LL (ANSI#300)
Hh**WR
850910635450610230
337/16
3513/16
251711/16
249
980980635450610272
389/16
389/16
251711/16
241011/16
11001100855590850290
435/16
435/16
335/8
231/4
337/16
117/16
12001200855600850310
471/4
471/4
335/8
235/8
337/16
123/16
12501250855600850
357.5
493/16
493/16
335/8
235/8
337/16
141/16
1450145015747401100490
571/16
571/16
6115/16
291/8
435/16
195/16
1650165016758601100498
6415/16
6415/16
6515/16
337/8
435/16
195/8
1850185016758601090603
727/8
727/8
6515/16
337/8
4215/16
233/4
Weight Kg/Ibs* 405 / 893 510 / 1124 822 / 1812 945 / 2083 980 / 2160 1950 / 4299 2070 / 4560 2600 / 5730Vol.control
chamber lit/gal 18.6 / 4.9 18.6 / 4.9 50 / 13.2 50 / 13.2 50 / 13.2 84 / 22.2 84 / 22.2 84 / 22.2
Globe Threaded TypeValve Size 40 (11/2”) TH 50 (2”) TH
mm inch mm inchTL 215 87/16 215 87/16
TH 185 75/16 185 75/16
h 140 51/2 140 51/2
TW 129 5 129 5TR 62 23/8 62 23/8
Weight kg/lbs* 7 / 15 7 / 15
H
L
W
AH
AR
AL
TH
TR
TL
R
TW
AB
h h
AW
H
L
W
AH
AR
AL
TH
TR
TL
R
TW
AB
h h
AW
Angle TypeValve Size 50 (2”) 80 (3”) 100 (4”) 150 (6”) 200 (8”) 250 (10”)
mm inch mm inch mm inch mm inch mm inch mm inchAL 208 83/16 250 913/16 295 111/16 405 16 505 197/8 585 23AH 240 97/16 415 165/16 445 171/2 570 227/16 635 25 832 323/4
AW 170 611/16 200 77/8 235 91/4 330 13 415 165/16 495 191/2
AR 107 43/16 138 57/16 147 513/16 180 71/16 302 117/8 338 135/16
AB 125 415/16 150 57/8 173 613/16 240 97/16 300 1113/16 338 135/16
Weight kg/lbs* 12 / 26 20 / 44 37 / 81 76 / 167 150 / 330 234 / 550
H
L
W
AH
AR
AL
TH
TR
TL
R
TW
AB
h h
AW
H
L
W
AH
AR
AL
TH
TR
TL
R
TW
AB
h h
AW
Grooved TypeValve Size 50 (2”) 80 (3”) 100 (4”) 150 (6”)
mm inch mm inch mm inch mm inchVL 215 81/2 351 1313/16 376 1413/16 521 201/2
VH 173 613/16 228 9 240 97/16 330 13 h 140 51/2 170 611/16 180 71/16 230 91/16
VW 128 5 197 73/4 236 95/16 331 131/16
VR 78 3 106 43/16 118 45/8 147.5 513/16
Weight kg/lbs* 6.5 / 14.5 15.1 / 33.25 26.5 / 58.5 58.25 / 128.5VH
H
VRVH
H
VRVW
VL
VW
VL
* Approximate shipping Weight (PN 25) ** h = Minimal required maintenance space
• End Connections (for PN16 or PN25)• ISO 2084, 2441, 5752 ANSI B16, AS2129, JIS B22
Series 300 Valves
Edition 02/2018
13
Engineering Data
Dimensions & WeightsModel 32 (25 bar rated valves)
Globe Flanged TypeValve Size 80 (3”) 100 (4”) 150 (6”) 200 (8”) 250 (10”)
mm inch mm inch mm inch mm inch mm inch
LH
h**WR
310185107200100
123/16
71/4
41/4
77/8
315/16
350232156235120
133/4
93/16
61/8
91/4
411/16
480250170300150
187/8
10 63/4
113/4
57/8
600334220360182
235/8
131/8
811/16
143/16
63/16
730395275425215
283/4
151/2
1013/16
163/4
87/16
Weight Kg/Ibs* 15 / 33 27 / 60 51 / 112 92 / 202 171 / 377Vol.control
chamber lit/gal 0.1 / 0.02 0.3 / 0.08 0.7 / 0.2 1.5 / 0.37 4.3 / 1.1
Valve Size 300 (12”) 350 (14”) 400 (16”) 450 (18”) 500 (20”) 600 (24”)mm inch mm inch mm inch mm inch mm inch mm inch
LH
h**WR
850545400489245
337/16
211/2
153/4
191/4
93/8
980635480610260
389/16
25187/8
24103/16
1100635480628314
435/16
25187/8
243/4
123/8
1200855600850310
471/4
335/8
235/8
337/16
123/16
1250855600850
357.5
493/16
335/8
235/8
337/16
141/16
12591311245881459
499/16
515/8
95/8
3411/16
181/16
Weight Kg/Ibs* 330 / 726 510 / 1124 544 / 1197 945 / 2083 980 / 2160 1030 / 2266Vol.control
chamber lit/gal 9.7 / 2.6 18.6 / 4.9 18.6 / 4.9 50 / 13.2 50 / 13.2 50 / 13.2
Grooved TypeValve Size 80 (3”) 100 (4”) 150 (6”)
mm inch mm inch mm inchVL 310 123/16 348 1311/16 480 201/2
VH 173 613/16 228 9 330 13h** 107 43/16 156 61/8 230 91/16
VW 128 51/16 197 73/4 331 131/16
VR 78 31/16 105 41/8 122 513/16
Weight kg/lbs* 6.5 / 14.3 15 / 33 48 / 105
* Approximate shipping Weight (PN 25) ** h = Minimal required maintenance space
• End Connections (for PN16 or PN25) • ISO 2084, 2441, 5752 ANSI B16, AS2129, JIS B22.
H
L
W
AH
AR
AL
TH
TR
TL
R
TW
AB
h h
AW
H
L
W
AH
AR
AL
TH
TR
TL
R
TW
AB
h h
AW
VH
H
VRVH
H
VRVW
VL
VW
VL
Series 300 Valves
Edition 02/2018
14
Engineering Data
Model 32 (25 bar rated valves)
Valve Size 80(3”)
100(4”)
150(6”)
200(8”)
250(10”)
300(12”)
350(14”)
400(16”)
450(18”)
500(20”)
600(24”)
Max. recommended flow rate for continuous operation (m3/h) 60 145 225 510 970 1400 1900 2030 3100 3600 3600
Max. recommended flow rate for continuous operation (Gpm) 265 640 990 2250 3990 6200 8400 8940 13660 15860 15860
Min. recommended flow rate <1 m3/h (<5 GPM)
Flow rate factor:Kv 43 115 165 345 663 1160 1600 1600 3000 3000 3000
Cv 50 133 192 400 770 1360 1900 1900 3500 3500 3500
Size Selection Tables
Models 30 (16 bar rated valves) / 31 (25 bar rated valves)
Valve Size 40 (11/2”)
50 (2”)
65 (21/2”)
80 (3”)
100 (4”)
150 (6”)
200 (8”)
250 (10”)
300 (12”)
350 (14”)
400 (16”)
450 (18”)
500 (20”)
600 (24”)
700 (28”)
800 (32”)
Max. recommended flow rate for continuous operation (m3/h) 25 40 40 100 160 350 620 970 1400 1900 2500 3100 3600 5600 7600 8135
Max. recommended flow rate for continuous operation (Gpm) 110 180 180 440 700 1600 2800 4300 6200 8400 11000 13660 15800 24700 33500 35840
Min. recommended flow rate <1m3/h (<5 gpm)
Globe Type
Flow Rate Factor: Kv (Metric)Cv (US)
4350
4350
4350
115133
167195
407475
676790
11601360
16001900
16001900
30003500
31503700
33003860
65007600
65007600
65007600
Head Loss Factor K (dimensionless) 2.2 5.4 15.4 4.8 5.6 4.8 5.5 4.5 5 9 3.8 6 5.9 4.8 8.9 15.2
Angle Type
Flow Rate Factor: Kv (Metric)Cv (US)
6070
6070
140164
190222
460537
770900
13101533
Head Loss Factor K (dimensionless) 1.3 2.8 3.3 4.3 4.3 4.2 3.6
For head Loss of fully open valves use the following equations:
H (Bar) = (Q [m3/h])2 H (Psi) = (Q [gpm])2 H = K V2 Kv Cv 2g
Series 300 Valves
Edition 02/2018
15
Engineering Data
Headloss Charts
100 1000 10,000 gpm50
3w 2w
1
10
10 1,000
2
3
4
5
6
8
100 10,000 m3/hr
mwc
2
3
4
5
678
109
psi
3"80
mm
4 "10
0mm
6 "15
0mm
8 "20
0mm
10"
250m
m
24"
, 20
",
18"
450m
m,
50
0mm
,
600m
m
MODEL 32 (GLOBE PATTERN) PRESSURE LOSS CHART
12"
300m
m
16"
,14
"35
0mm
,
400m
m
w 3 w 2
1
0 1
0 0 0 , 1 0 1
2
3
4
5
6
8
0 0 1
001
0 0 0 , 0 1 m 3 r h / m p g
c w m
2
3
4
5 6 7 8
0 1 9
i s p
3 "
8 0 m
m
4 "
1 0 0 m
m
6 "
1 5 0 m
m
8 "
2 0 0 m
m
1 0 "
2 5 0 m
m 1 8
" , 2 0
" , 2 4
" 4 5
0 m m
, 5 0 0
m m
, 6 0 0
m m
T R A H C S S O L E R U S S E R P ) N R E T T A P E B O L G ( 2 3 L E D O M
1 2 "
3 0 0 m
m 1 4
" , 1 6 "
3 5
0 m m
, 4 0 0
m m
000,1 000,01
w 3 w 2
1
0 1
0 0 0 , 1 0 1
2
3
4
5
6
8
0 0 1
001
0 0 0 , 0 1 m 3 r h / m p g
c w m
2
3
4
5 6 7 8
0 1 9
i s p
3 "
8 0 m
m
4 "
1 0 0 m
m
6 "
1 5 0 m
m
8 "
2 0 0 m
m
1 0 "
2 5 0 m
m 1 8
" , 2 0
" , 2 4
" 4 5
0 m m
, 5 0 0
m m
, 6 0 0
m m
T R A H C S S O L E R U S S E R P ) N R E T T A P E B O L G ( 2 3 L E D O M
1 2 "
3 0 0 m
m 1 4
" , 1 6 "
3 5
0 m m
, 4 0 0
m m
000,1 000,01
Model 32 (Globe Pattern) Pressure Loss
Models 30/31 (Globe Pattern) Pressure Loss Chart
Models 30A/31A (Angle Pattern) Pressure Loss Chart
w 3 w 2
1
0 1
0 0 0 , 1 0 1
2
3
4
5
6
8
0 0 1
001
0 0 0 , 0 1 m 3 r h / m p g
c w m
2
3
4
5 6 7 8
0 1 9
i s p
3 "
8 0 m
m
4 "
1 0 0 m
m
6 "
1 5 0 m
m
8 "
2 0 0 m
m
1 0 "
2 5 0 m
m 1 8
" , 2 0
" , 2 4
" 4 5
0 m m
, 5 0 0
m m
, 6 0 0
m m
T R A H C S S O L E R U S S E R P ) N R E T T A P E B O L G ( 2 3 L E D O M
1 2 "
3 0 0 m
m 1 4
" , 1 6 "
3 5
0 m m
, 4 0 0
m m
000,1 000,01
w 3 w 2
1
0 1
0 0 0 , 1 0 1
2
3
4
5
6
8
0 0 1
001
0 0 0 , 0 1 m 3 r h / m p g
c w m
2
3
4
5 6 7 8
0 1 9
i s p
3 "
8 0 m
m
4 "
1 0 0 m
m
6 "
1 5 0 m
m
8 "
2 0 0 m
m
1 0 "
2 5 0 m
m 1 8
" , 2 0
" , 2 4
" 4 5
0 m m
, 5 0 0
m m
, 6 0 0
m m
T R A H C S S O L E R U S S E R P ) N R E T T A P E B O L G ( 2 3 L E D O M
1 2 "
3 0 0 m
m 1 4
" , 1 6 "
3 5
0 m m
, 4 0 0
m m
000,1 000,01
100 1000 10,000 gpm50
1
10
10 1,000
2
3
4
5
6
8
100 10,000 m3/hr
mwc
2
3
4
5
678
109
psi
2½"
, 2 ",
1½"
40m
m,
50m
m,
65m
m
3"80
mm
4"10
0mm
6 "15
0mm
8 "20
0mm
10"
250m
m 14"
, 12
"30
0mm
,
350
mm
20"
,18
",
16"
400m
m,
45
0mm
,
500
mm
32"
,28
",
24"
600m
m,
70
0mm
,
800
mm
MODELS 30 \ 31 (GLOBE PATTERN) PRESSURE LOSS CHART
3w 2w
1
10
10 1,000
2
3
4
5
6
8
100 10,000 m3/hr
mwc
2
3
4
5
678
109
psi
1½",
2 "40
mm
,
50m
m
3"80
mm
4"10
0mm
6 "15
0mm
8"20
0mm
MODELS 30A \ 31A (ANGLE PATTERN) PRESSURE LOSS CHART
10"
250m
m
3w 2w
100 1000 10,000 gpm50
w 3 w 2
1
0 1
0 0 0 , 1 0 1
2
3
4
5
6
8
0 0 1
001
0 0 0 , 0 1 m 3 r h / m p g
c w m
2
3
4
5 6 7 8
0 1 9
i s p
3 "
8 0 m
m
4 "
1 0 0 m
m
6 "
1 5 0 m
m
8 "
2 0 0 m
m
1 0 "
2 5 0 m
m 1 8
" , 2 0
" , 2 4
" 4 5
0 m m
, 5 0 0
m m
, 6 0 0
m m
T R A H C S S O L E R U S S E R P ) N R E T T A P E B O L G ( 2 3 L E D O M
1 2 "
3 0 0 m
m 1 4
" , 1 6 "
3 5
0 m m
, 4 0 0
m m
000,1 000,01
w 3 w 2
1
0 1
0 0 0 , 1 0 1
2
3
4
5
6
8
0 0 1
001
0 0 0 , 0 1 m 3 r h / m p g
c w m
2
3
4
5 6 7 8
0 1 9
i s p
3 "
8 0 m
m
4 "
1 0 0 m
m
6 "
1 5 0 m
m
8 "
2 0 0 m
m
1 0 "
2 5 0 m
m 1 8
" , 2 0
" , 2 4
" 4 5
0 m m
, 5 0 0
m m
, 6 0 0
m m
T R A H C S S O L E R U S S E R P ) N R E T T A P E B O L G ( 2 3 L E D O M
1 2 "
3 0 0 m
m 1 4
" , 1 6 "
3 5
0 m m
, 4 0 0
m m
000,1 000,01